DE3204843A1 - BATTERY SUPPLY - Google Patents

Description

Western Electric Crt. ImSl .. ", . * · ..". AULL, DW 1-2

—5—
Battery feed circuit

The invention relates to a battery feed circuit for a two-wire communication path.

A battery feed circuit provides a feed • . direct current for communications equipment via one A two-wire transmission path which "typically also includes a bidirectional voice or data signal leads. This supply current is symmetrical, i.e. each transmission wire carries a current of the same size, • but opposite direction to the current in the other wire.

In communication systems, the length of the two-wire transmission paths varies considerably. Therefore the Battery feed circuit should be designed so that it provides the required DC feed current in a range of Provides resistance values for the path. In the case of transmission paths, induced longitudinal or common-mode signals also occur on, for example, 60 or 50 Hz network signals that can be converted into interference. It is therefore necessary that the battery feed circuit the transformation of solpher common-mode signals' keeps it as small as possible in disruptions.

A variety of battery feed circuits have been developed. In general, these can be Divide circuits into two classes depending on their food profile, ie. the dependence of the direct feed current on the voltage over the two-wire transmission path, as well as the way in which common-mode signals will be treated »-The first class of battery feed circuits, for example, accordingly der-'US-PS 4 004 109, generates a linear battery feed profile and has a low common mode impedance for line signals. In this first class of

* * ft

-6-

Feed circuits are used on the two-wire transmission path Reduced interference induced by the common-mode signals with little success. Furthermore Although such circuits have proven themselves in many applications, the use of a linear battery feed profile however, it leads to large power losses in the case of short two-wire transmission paths. The second Class of battery feed circuits, for example according to the publication "A Floating Low-Power Subscriber Line Interface "by L. Freimanis and D.P. Smith, ISSCC Digest, 1980, pp. 180, 181 Non-linear battery feed profile that limits the feed current for short two-wire transmission paths. The interference induced by common-mode signals is

T5 den due to a high common mode impedance through use reduced by isolation devices, for example transformers or optocouplers. However, such components are expensive and space-consuming .

The invention is based on the task ©, a battery storage se circuit to create the ones discussed above Avoids disadvantages.

To achieve the object, the invention is based on a battery feed circuit for a two-wire communication path and is characterized in that the circuit comprises the following components:

a first and a second bidirectional power source for connection to the first and second wires of the path; a first feedback circuit having circuits that responding to the push-pull voltage along the way generate a control signal; and

a second feedback circuit for generating a second control signal while monitoring the common-mode voltage of the way that the first current source under-speak a first direct current to the control signal

convinced that the second power source is responding a second direct current is generated on the control signal, the same size - but opposite direction as the "first has direct current, and that the first and the . 5 second current source the first or second direct current depending on the second control signal by an equal Change the amount to maintain a constant difference between the currents.

According to the present invention, a symmetrical supply direct current on a two-wire communication path generated. The direct current on each wire of the two-wire path is bidirectional Power source supplied. Each power source is powered by one Control signal of a complementary pair of first control signals regulated together with a second control signal. The current source supplies a non-linear battery feed profile as a function of the complementary pair of first control signals. The pair of control signals is generated by a feedback circuit that controls the push-pull voltage monitored on the W.eg. A second feedback circuit, which is the common mode voltage on the The two-wire path is monitored and the second control signal is generated from it, providing a low common-mode impedance for longitudinal signals. This second control signal influences every bidirectional current source by the same Value so that a constant difference between the direct currents on each wire is maintained. Accordingly the induced common-mode interference is brought to a minimum.

The invention is described below with reference to the drawings. Show it:

1 shows the block diagram of a battery feed circuit according to the invention;

Fig. 2 is a graphic representation of the nichtlinen.ron dpelseprofils according to the invention;

Fig. 3 is a more detailed circuit diagram of the circuit of Fig. 1;

Fig. 4 shows a modification of the non-linear feedback circuit 105 according to FIG. 2, which with further circuits for the provision of Features that are required in many communication systems;

Fig '. 5 (on the same sheet as FIG. 2) is a graph of the nonlinear Feed profiles that can be achieved with the circuit according to FIG. 4.

1 shows, as an example, an application of the invention in a communication system. A two-wire communication channel with metallic wires 101 and 102 transmits bidirectional voice or data signals between a part subscriber station 120 and a standard four-wire interface circuit in a telephone exchange. Such a two-wire message path is usually called a subscriber loop referred to, the wires 101 and 102 being referred to as a- and b-wire. The length and -with it the resistance of the tip and ring wires between the telephone exchange and the subscriber device can vary from subscriber to change participants greatly. It should be noted that the two-wire communication path also becomes a Two-wire dialer instead of a subscriber set. In such cases, the two-wire communication path also referred to as a connecting line.

A supply direct current for the subscriber set 120 is from a bidirectional power source 103, which is via a protective resistor 113 is connected to the a-wire, and a bidirectional current source 104 is supplied, which is connected to the b-wire via a protective resistor 114. The protective resistors are required in order to avoid the destruction of the battery supply circuit in the event of lightning strikes. A typical value for each protective resistor is 100 ohms. Each electricity

source becomes a negative constant potential Vg ^. and earth ~ potential supplied. According to the agreement, the

Direct current from the tip to the ring. This current flow direction of the supply current is also referred to as normal battery voltage (NB). In addition, the supply current I _{111n is} symmetrical, ie the current on the a and

XK >

b-veins are the same size but flow in opposite directions Direction.

The size of the supply current is regulated by a (differential) push-pull feedback circuit 105, which is connected to the tip and ring wires via lines 106 and 107. 10 is switched on. The push-pull feedback circuit 105 monitors the differential or push-pull voltage Vmn between the tip and ring wires and generates control signals * S ₁ and L which are fed to current sources 103 and 104 via lines 115 and 116, respectively. The control signals S ₁ and S ,. are complementary signals, that is, they are of the same size but opposite polarity, and are a non-linear function of the voltage Vm _R. This advantageously reduces the power consumption by providing a non-linear battery feed profile that limits the feed current for short tip and ring wires.

FIG. 2 shows the non-linear battery feed profile provided _{by the control signals S 1 and S.} Nominally, the value of Vmn falls between V ₁ and V ₂ , and the supply current follows the line section A. For smaller values of V _TR between V ^ and V ₂ , the normal battery supply current follows section B and ranges between Ι _χ and ImA _x . Section C shows that the magnitude of the supply current is independent of the drop in voltage V _ljL , _R below V * to Ί. ^ is limited. On practical models, I _MA y was 42 mA and _χ 32 mA. The gradient of the line sections A, B and C was 300 ohms, 2600 ohms and> 30,000 ohms, respectively.

It is known that longitudinal currents (common mode currents) from different sources can be induced on the a ~ and b wires. Fig. 1 shows a typical 60 Hz DC

clock source 108. This induces a common mode current Ij, which flows on the two wires a and b in the same direction. The total current L · on the tip wire is equal to the difference between I ^ n and I _L. The total current Ip on the b-wire is equal to the sum of I _TR and Iv. Since the value of Ir _{can exceed the value of I 1} ,,., It is possible to reverse the total current on either the a ~ or the ring wire. Since the current sources 103 and 104 are bidirectional and linear when the current is reversed, ie run linearly through the origin, this current reversal does not generate any disturbances. Any push-pull voltage generated by the series or common mode current Ir represents an undesirable disturbance. The measure of how well a circuit reduces such disturbance is generally referred to as the series symmetry of the circuit. The induced common-mode interference can be reduced to a minimum by generating the same and low common-mode impedance for the tip and ring.

According to the present invention, a low common clock impedance of the tip and ring wires is achieved by a Common mode feedback path to current sources 103 and 104 causes. As will be explained later the same common-mode impedance values of the tip and ring wires are achieved by changing the transconductance of the current sources and 104 are matched to one another.

The common-mode feedback path comprises resistors 111, 112 of equal size, lines 117, 118 and a common-mode feedback circuit 109. This circuit 109, which is supplied as a reference value ΒΛΤ / 2, monitors every change in the common-mode voltage or average voltage at node 110, which is caused by the occurrence of longitudinal signals, and generates a control signal S ₂ - This signal is fed via a line 117 to current sources 103, 104 and causes them to compensate for a stroin supplied by a common mode source of the tip and ring wires *. This procedure will

Called longitudinal extinction. Accordingly, there is a constant difference between the feed current on the tip wire. and b ~ vein maintained.

Reference is now made to FIG. The current source 103 has a differential operational amplifier 301 and resistors 302, 303, 304, 305 and 306. The value of the input resistors 303 and 304 is the same, and the same applies to the value of the feedback resistors 302 and 305. Control signals S ₁ and S _{2 are} fed to the positive and negative inputs of the operational amplifier 301, respectively. The differential operational amplifier 301 advantageously supplies an output current in one of both directions to the protective resistor 113. The magnitude of this output current 15 is equal to the difference between the control signals S ₁ and S ₂ , multiplied by the transconductance of the current source. This transconductance is equal to the value

'-. Resistor 302
/. Resistor 304) (resistor 306)

The current source 104 has a differential operational amplifier 310 and resistors 311, 312, 313, 314, 315. Each resistance in the current source 104 has the same value as the corresponding resistance in the current source 103. The control signals S ₁ and S ₂ are fed to the positive and negative inputs of the operational amplifier 310, respectively. Since the structure of the current source 104 is the same as that of the current source 103, the output current of the current source 104 can again flow in both directions, and the transconductance of the current sources 103 and 104 is the same. The output current of the source 104 has a value equal to (S ₁ -S ₂ ) times the value of · ^{Bel. The} absence of longitudinal signals causes the application of the signal S ₁ to the current source 103 to generate a preselected current which flows into the tip wire. At the same time, the

apply the control signal S ^ to the current source 104 an equal current that flows from the b-wire via the output of the operational amplifier 310 to V _ßAT .

The control signals S. and S ,. are through the push-pull feedback circuit 105 generated. The positive input of operational amplifier 320 in feedback circuit 105 is via line 106 to the tip wire and the negative input connected to the ring via line 107. The input resistors 322 and 323 are the same. Resistors 321 and 324 are also the same. Operational amplifier 320 provides an output s' voltage equal to the push-pull voltage V., ^ between the a ~ and b veins, multiplied by the tow of

. The output voltage of the amplifier

320 gives both the DC voltage generated by the output currents of the current sources 103 and 104., And any alternating voltage that represents the data or voice signals on the tip and ring wires. This output voltage is led to the transmission side of a four-wire interface circuit, where the DC voltage is blocked so that only the AC component can be transmitted. The output signal of the operational amplifier 320 is also fed to the negative input of differential amplifier 325 via resistor 329.

The differential amplifier 325 provides one of three different gain values, depending on the value of the output voltage of the amplifier 320. This change in the gain value changes the gain of the circuit 105 as a function of V _TR and therefore the magnitude of the control signals S ^ and S ^, in order to achieve what is shown in FIG 2 to generate the non-linear battery feed profile.

The slope value of the line segments A, B and C in Ohm is equal to the reciprocal of the product of the

Transconductance of current sources 103 or 104 and half the gain of circuit 105. Section A is generated when the gain of differential amplifier 325 is equal to the value 'j'Frnd''29 ^is ^ '^ ^{03 s} P ^{eir> e} profile follows the section B if the gain of amplifier 325 equals the value

(resistance ⁺ W ^^ M ^ t) Erstand 329 Finally, a gain of amplifier 325 results in equal to the value of

- ■ ■ - ■ -2 - ——

/ 1 1 1 ^

(resistance 328 ⁺ resistance 327 ⁺ resistance 326 / ^{¥ ide} .rst.329 to the essentially horizontal section C.

The negative input of the differential amplifier 325 is also connected to the current source 350 which defines the intersection point V ^ of the axis V, ™ In Flg. 2 determined. The current source 350 is designed in a special way so that it leads to an intersection whose value is equal to a threshold voltage V ™ minus the battery voltage V _BAT . This ensures that amplifiers 301 and 310 remain properly biased, ie

not reaching saturation when there is an interruption occurs between the tip and ring and no feed current is generated. This creates a longitudinal extinction together with voice and data transmission regardless of the presence or absence of a feed stream maintained.

The filter 360 with the resistor 361 and the Kondenca- ■ tor 330 eliminates voice or data ac voltage components in the output voltage Sq of the differential amplifier 325. A filter time constant of 200 ms is a useful value. ·. . ·

Note that the output voltage S _{Q of} the differential amplifier 325 is referenced to ground and that the

, S ₁ and Sj on V ^, ₍ , / 2 be20p; on «Ind. Einr: Shift of the voltage reference point to V _BA ," / 2 v;: l..rcl. By the current source 331, the resistors 332, 333, 338, 339, the emitter-coupled transistors 334, and the differential amplifiers 336, 337. The value of the current Ij ^ - in Fig. 2 is directly proportional to the current supplied by the current source 331. Accordingly, Ij ^ can be obtained by changing the value of the Current source 331 supplied current can be adjusted.

The transistors 343, 344, the current source 340 and the resistors 341, 342 couple data or speech alternating voltages, representing incoming or capture signals to differential amplifiers 336 and 337. Accordingly, these alternating current signals also reach current sources 103, 104 and via lines 115, II6 then to the a and b wire.

The common mode feedback circuit 109 includes a differential amplifier 350 and resistors 351, 352. The positive input of differential amplifier 350 monitors the common-mode voltage at node 110, while the negative input of differential _{amplifier 350 is connected to Vg A} rp / 2 as the reference voltage. The common mode impedance of the a-wire in ohms is the same:

, Resistor 351 T7 ' ⁺ Resistor 352 ) ^u 103 where G ₁₀ ^ is the transconductance of the current source 103. The common mode impedance of the b-wire is the same:

1

f. Resistor 551 ^ _P 'V Resistor 352 / ^u 104

where G ^ _ο λ is the transconductance of the current source 104. The value of the common mode impedance of the tip and ring wires is advantageously chosen to be equal to the sum of the resistors 113, 306 or equal to the sum of the resistors 114, 3 ^ 5. This choice results in a constant output voltage of the differential amplifiers 301 and 310 regardless of the value of any longitudinal currents. Accordingly, it becomes the allowable

• -15-

Voltage fluctuation at the output of both differential amplifiers 301 and 310 are not reduced by the size of the longitudinal streams. The longitudinal extinction is only permissible through the Voltage fluctuation at the output the Differenr.vfir-.5 amplifier 350 and the output current available from the differential amplifiers 301 and 310 is determined. As a result Longitudinal cancellation can be achieved for induced currents that are significantly larger than the supply current are.

Low common mode impedance is achieved by selecting the ratio of resistors 351 and 352. The longitudinal symmetry is achieved by adapting the transconductance of the current sources 103 and 104. Since these current sources can advantageously be implemented using integrated circuits, such an adaptation can easily be achieved by adjusting the value of the corresponding resistors. In connection with this, it should be pointed out that the protective resistors 113, 114 do not affect the common-mode impedance of either the tip or ring. Accordingly, it is not necessary to adapt the resistors 113, 114 for longitudinal symmetry. This feature is particularly useful, since the equalization of protective resistances that have to withstand lightning strikes is much more complex than the equalization of resistances in the power sources • 103 and 104.

Referring to Fig. 4, the above-described battery feed circuit can easily be adapted to provide several features required in communication systems.

The push-pull feedback circuit 405 is identical with the circuit 105 with the exception of the additional switch 406 and the current source 407. Dor switch 4o (i, for explanation as. mechanical switch shown is either by the power feed shutdown control signal (FS) or controlled by the battery reversal control signal (RB). Both signals are two-stage

Logic signals which are fed out in signaling devices which are connected to the four-wire interface circuit. A predetermined state (for example logic 0) of the two control signals RB and FS applies the switch 406 to the connection 1 in order to connect the current source 350 to the negative input of the differential amplifier 5-5. As described above, this gives the normal battery profile shown in FIG. A logic 1 for the control signal RB brings the switch 406 to the connection 3, whereby the current source 407 is connected to the negative input of the differential amplifier 325. The current source 407 is identical to the current source 350 with the exception of a polarity reversal. .

15. The connection of the current source 407 reverses the polarity the control signals S ^ and S ^ um. As a result, the normal current flow on the tip and ring reversed. The reverse battery feed profile (RB) in FIG equal and opposite to the normal food profile (NB) that is normally present. A reverse Battery profile is required for signaling when the two-wire wires 101 and 102 are interconnect wires are that instead of a subscriber station 120 to a two-wire dialer or a private secondary

25 · are connected. At. other trunking applications a feed current is not required. In these cases a logical 1 of the control signal FS that the switch 406 is connected to the terminal 2, whereby the negative 'input of the Differential amplifier 425 remains open. The resulting feed current shutdown profile is shown in FIG. During the disconnection of the supply current, the longitudinal symmetry is maintained, since the operation of the common-mode feedback circuit 109 is unaffected.

The loop closure signal LC is another two-stage Logic signal sent by others to the four-wire interface circuit connected news

equipment is needed. A change in the state of the logic signal LC is brought _{about by a predetermined change in the value of V TR} ". This predetermined change of typically 3 V indicates dialing pulses and / or an off-hook state of the subscriber station 120. A special state, for example logic 1, of the logic signal LC can can easily be generated by an additional loop closure detector 408. This has a comparator which generates a logical 1 for the signal LC when the output signal of the differential amplifier 325 exceeds a fixed threshold value.

The switch 409 and the switch control 410 can ' also useful together with the creation of a Battery reversal and a loop closure signal may be provided. The switch 409, which is in parallel with the filter 360 is switched, if a change is detected ■ either the signal LC or the signal FlB closed briefly (nominally 16 ms) by the switch control 410. Briefly closing switch 409 bypasses filter 3βθ to avoid distortion and delay to be avoided in the event of dial pulses or transitions between normal and reverse battery supply.

Claims (14)

BLUMBACH * '"WESEH'- ΒΕΓΓβΕΜ · KRAMER ZWIRNER ■ HOFFMANN PATENT LAWYERS IN MUNICH AND WIESBADEN Palenlconsult Radeckestrasse 43 8000 Munich 60 Teleion (08?) 883603/883604 Telex 05-212313 Telegrams Patenlconsult Patentconsult Sonnenberger Stroße 43 6200 Wiesbaden Telephone (06121) 562943/561998 Telex 04-186237 Telegromme Paientconr.ult Western Electric Company Incorporated AULL, D.W. 1-2 • New York, -W.Y. 10038, USA Claims (Ώ Battery feed circuit for a two-wire. • message channel, characterized in that the battery feed circuit includes the following components: first and second bidirectional current sources (103, 104) for connection to the first and second wire (101, 102) of the path; A first feedback circuit (105) with echoes (320 to 329, 350), the under. Response to the Push-pull voltage (Vmp) on the way a control signal Generate (Sq); and a second feedback circuit (109) for generating a second control signal (S ₂ ) while monitoring the common mode voltage of the path; that the first current source (103) _{generates a first direct current (I TR} ) in response to the control signal, that the second current source (104) generates a second direct current in response to the control signal, the same size but opposite in direction as the first direct current has, and that the first and second current sources (103, 104) change the first and second direct current, respectively, depending on the second control signal (S ₂ ) by an equal amount in order to maintain a constant difference between the currents. Munich: R. Kramer Dipl.-Ing. -W. Weser Dipl.-Phys. Dr. rer. nat. - E. Hoffmann Dipl.-Ing. Wiesbaden; PG Blumbach Dipl.-Ing. ■ P. Bergen Prof. Dr. jur. Dipl.-Ing., Pat.-Ass., Pat.-Anw. until 1979 ■ G. Zwirner Dipl.-Ing. Dipl.-W.-Iny 2. Battery feed circuit according to claim 1, characterized in that the first feedback circuit (105) further comprises circuits (332 Ms 344) which, in response to the control signal (S _Q ), a first control signal (S ^) and the complement (S _-1 ) generate the first control signal that the first source (103) generates the first direct current as a function of the first control signal (S ..), and that the second source (104) the second direct current, the same size and '10 has the opposite direction as the first direct current, depending on the complement of the first control signal generated. 3. Battery feed circuit according to claim 1, ■ indicates that the first feedback circuit bias the first and second current sources (103, 104) so that saturation is prevented when a ■ Interruption between the first and second wire (101, 102) occurs. '. . 4. Battery feed circuit according to claim 1, characterized in that the first feedback circuit comprises circuits (406, 407) which respond under on a predetermined state of a supplied control signal (RB) the direction of the first and second direct current reverses. 5. Battery feed circuit according to claim 3, characterized in that the first feedback circuit (105) circuits (406, 407) which in response to a predetermined state of an applied control signal (RB), the direction of the first and second direct current reverses. 6. Battery feed circuit according to claim 4, characterized in that the first feedback circuit (105) has a component (4θβ, terminal 2), that under "responding to a predetermined condition t I a β a «· ·. -3- • the generation of a second supplied control signal (FS) of the first and second direct current blocks. 7. Battery feed circuit according to claim 5, characterized in that the first feedback, ·> ■ The circuit (105) has a component (406, connection Z) which, in response to a voi-determined tone state of a second control signal (FS) supplied, blocks the generation of a first and second direct current. 8. battery feed circuit according to claim 1, characterized in that the first feedback circuit (105) has a detector (408), the a predetermined change in the push-pull voltage on the Notices the message path. 9. battery feed circuit according to claim 3, characterized in that the first feedback circuit ^ 105) has a detector (408) which has a determines predetermined change in the push-pull voltage on the Nachricntenweg. 10. Battery feed circuit according to claim 4, characterized in that the first feedback circuit (105) comprises a detector (408) having a determines a predetermined change in the push-pull voltage on the communication path, 11. battery feed circuit according to claim 5, characterized in that the first feedback circuit (105) comprises a detector (408) having a predetermined change in push-pull voltage on the Message path, notes. 12. Battery feed circuit according to claim 6, characterized in that the first feedback circuit (105) comprises a detector (408) having a determines predetermined change in the push-pull voltage on the communication path. 13. Battery feed circuit according to claim 7, characterized in that the first feedback circuit (105) has a detector (408) which detects a predetermined change in the push-pull voltage on the Notices the message path. · · 14. ßatteriespeiseschaltung according to claim 10, 11, 12 or 13, characterized in that the first feedback circuit (105) has a switching device (409, 410), the detection of the predetermined change in the push-pull voltage or a change in state of the 2ugleitungs control signal a filter (360) in the first feedback circuit for a predetermined time bypasses